Kidney_Block__2024_L1-2 (2).pdf

Full Transcript

Kidney Physiology
Lecture

Presented by
Ronald Castelino
A/Prof in Clinical Pharmacy
[email protected]

The University of Sydney Page 1
The University of Sydney Page 2
 LEARNING OBJECTIVES
– The aim of this session is to provide you with enhanced
knowledge and skills to assess patient’s renal function and
manage patients with chronic kidney disease, end stage kidney
disease and acute kidney injury. It will also provide an
introduction to renal replacement therapy.

– Lecture 1& 2
– List the main functions of the kidney

– Describe & interpret the tests used to investigate kidney
function

– Acute Kidney Injury (AKI)

The University of Sydney Page 3
 URINARY SYSTEM

– Kidneys x 2
– Urinary bladder – temporary
storage for urine
– Ureter x 2 – urine transport:
kidney to bladder
– Urethra – urine from bladder to
external

The University of Sydney Page 4
 – What are the functions of the
kidney?

The University of Sydney Page 5
 – Functions of the kidney
– Excretory functions

– Endocrine functions

– Regulatory functions

– Metabolic functions

The University of Sydney Page 6
― Kidneys-Two sections
― Outer cortex
― Inner medulla
― The functional unit of the kidney is Nephron
― Approximately one million in each kidney
― capable of forming urine
― Two major components:
– Glomerulus
– Tubular system
Proximal tubule
Diluting segment
Distal tubule
Collecting duct

The University of Sydney Page 7
The University of Sydney Page 8
 Arcuate
branches
― Renal blood supply:
― 20% of the cardiac
output
― Blood flow to the
medullary region is
poor at the best of
time; risk of hypoxia
significant
Afferent
― Vascular supply: arteriole
― renal arteries—
interlobar arteries— Efferent
arcuate arteries—
interlobular arteries Arteriole
― afferent arterioles—
glomerular
capillaries—efferent Peritubular
arterioles—peritubular capillaries
capillaries
The University of Sydney Page 9
 Steps in urine formation
― Filtration:
― Filtration only takes place in the renal corpuscle.
― 180 liters of fluid is filtered by the nephrons in one day!!

― Reabsorption
― Reabsorption occurs when filtered material is moved back into the
blood,

― Secretion
― while secretion removes selected material from the blood and places it
in the filtrate.

The University of Sydney Page 10
11

The University of Sydney Page 11
12

The University of Sydney Page 12
 ― The glomerulus is a high-pressure filtration system composed of a
specialized capillary network.
― Blood supplied to the glomerulus through the Afferent Arterioles (AA) and
removed by the Efferent Arterioles (EA)
― Large molecules are generally unable to pass through the glomerular
membranes
― It generates an ultra filtrate that is free of blood and significant amounts of
blood proteins.
― Ultra filtrate passed into the tubular system for processing eg reabsorption
of water & electrolytes, regulation of concentration, etc
― Glomerular filtration rate (GFR) is a key marker of renal function
― Index of renal function would thus ideally measure GFR

The University of Sydney Page 13
 GFR usually maintained by factors such as cardiac output,
SNS tone, blood pressure, vascular volume, etc

Glomerulus
Afferent arteriole Efferent arteriole

Urine Output
The University of Sydney Page 14
 Reduction in any of these drivers will lead to reduced GFR
and hence urine production

Glomerulus
Afferent arteriole Efferent arteriole

The University of Sydney Page 15
 ― A feedback mechanism that keeps renal blood flow (RBF) and GFR constant
despite changes in arterial blood pressure.
― As RBF increases, GFR increases, leading to an increase in NaCl delivery to
the macula densa.
― a feedback loop through the macula densa to the juxtaglomerular cells of
the afferent arteriole results in increased vascular tone, decreased renal
blood flow and a decrease in GFR.
― NaCl to the macula densa then decreases leading to relaxation of the
afferent arteriole (increasing glomerular hydrostatic pressure) and increases
renin release from juxtaglomerular cells of afferent and efferent arterioles
― renin increases angiotensin I, then converted to angiotensin II which constrict
efferent arteriole increasing hydrostatic pressure returning GFR to normal

The University of Sydney Page 16
 The kidneys have inbuilt physiological defense measures to counteract reduced
inflow using Prostaglandins and Angiotensin II
In conditions of stress to the kidneys (eg CKD, DM, HTN, CCF) these mechanisms
become increasingly important to maintain GFR.

PGs ATII
Glomerulus
Efferent arteriole
Afferent arteriole
Constriction
Dilation

The University of Sydney Page 17
 Physiology of renal blood flow

The University of Sydney Page 18
 Urine = GF –TR+ TS
The University of Sydney Page 19
The University of Sydney Page 20
 Urine = GF –TR+ TS
The University of Sydney Page 21
 + -
arterial pressure

Glomerular hydrostatic pressure

GFR
Proximal tubule
NaCl reabsorption

macula densa NaCl

renin

angiotensin II

afferent arteriolar
efferent arteriolar resistance
resistance
The University of Sydney Page 22
The University of Sydney Page 23
 Q&A

The University of Sydney Page 24
Evaluation of Kidney
Function

Presented by
Ronald Castelino
A/Prof in Clinical Pharmacy
[email protected]

The University of Sydney Page 25
The University of Sydney Page 26
 Evaluate organ function
Determine extent of kidney disease (stage)
Determine appropriate management (action plan) if kidney
disease is an issue
Determine appropriate dose for drugs excreted through the
kidney
Prevent further damage by using nephrotoxic agents

The University of Sydney Page 27
 Glomerular filtration rate (GFR): is the rate (volume
per unit of time) at which ultra filtrate is formed at the
glomerulus.
GFR primary measure of renal function & hence
critical knowledge to evaluate drug dosage
Normal is 100 to 120 ml/min
Cannot be measured directly
An Ideal filtration marker should be filtered with no
reabsorption or secretion
Filtration markers:
Exogenous (e.g. Inulin, sinistrin, iohexol, iothalamate)
Endogenous (e.g. Serum Creatinine, Cystatin C)

The University of Sydney Page 28
 – Creatinine
– Urea
– Substances which we measure that give
approximations
Note: Albuminuria and Haematuria are signs of kidney
damage and may also used in the diagnosis of kidney
diseases

The University of Sydney Page 29
 Urea

End product of protein and amino acid catabolism
– serum urea concentrations are influenced by both rate of protein
breakdown and renal urea excretion
Filtered at glomerulus & reabsorbed in tubules (40-60%)

A relatively insensitive marker of renal function

Usually measured along with serum creatinine

The University of Sydney Page 30
 Reference Interval for Creatinine
Male 60-120 micromol/L
Female 50-110 micromol/L

Waste product of muscle metabolism
— formed by the liver via breakdown of creatine (from muscle)
— usually produced at a constant rate dependent on muscle mass
Excreted by kidney - glomerular filtration (10% via secretion)
— SCr is both a reflection of both muscle mass and kidney function
— SCr is inversely proportional to glomerular filtration rate
— doubling of SCr (even within the reference range) represents a 50% reduction
in renal function
Good indicator of renal function (better than urea)

The University of Sydney Page 31
The University of Sydney Page 32
Serum Creatinine may be quite misleading as the sole measure of renal function
Alternative methods of evaluation necessary eg Creatinine Clearance, eGFR
The University of Sydney Page 33
 Case Examples

– Example 1:
– An 80 year old, 172 cms height, 70 kgs and a SCr of 100 micromol/L
will have a creatinine clearance (CrCl) of 52 ml/min
– A 20 year old, 172 cms height, 70 kgs and a SCr of 100 micromol/L
will have a CrCl of 104 ml/min
– Example 2:
– Mrs SP presents to RHH with throbbing headache & nausea. She is 32
years old, 60kgs, 165 cms
– PMH: liver transplant at 2, previous rejection, migraine, depression &
reflux
– On tacrolimus 3mg m & 2mg n, amitriptyline 25mg n, esomeprazole
40mg m, prednisolone 7mg m, nicotine patches

The University of Sydney Page 34
 Case Examples

– Example 2 Continued:
– GP ordered tacrolimus levels. Tacrolimus levels were 37.8 micrograms/L
(very high-so referred to RHH)
– Patient states that she bought fluconazole for thrush from pharmacy
– SCr: 51 micromol/L (Day 1), 96 micromol/L (Day 2)
– CrCL: 133 ml/min (Day 1), CrCl: 70 ml/min

The University of Sydney Page 35
 (140- Age (yrs)) X Weight (kg)
Creatinine Clearance =
(ml/min)
0.815 X Serum Creatinine(micromol/L)

X 0.85 for women
Assumptions: relatively stable renal function; normal muscle
mass for age, sex, weight;
Recommended for renal dosing of medications
Not corrected for BSA
The University of Sydney Page 36
 IBW needed for Cockcroft & Gault calculation as creatinine
produced by muscles, and hence relies on muscle mass only

IBW men (kg) = 50 + (0.9 x height in centimetres > 152 cm)
IBW women (kg) = 45.5 + (0.9 x height in centimetres > 152
cm)

Note: if individual is under IBW, use actual body weight in
calculation (not IBW)

The University of Sydney Page 37
 Grade Creatinine Clearance

Mild 25-50 mL/min

Moderate 10-25 mL/min
AMH 2021
Severe 60mL/min/1.73m2
– More appropriately categorises individuals with respect to long-term clinical risks
of end-stage kidney disease, CHD, stroke and all cause mortality than MDRD.
– Has now replaced MDRD equation as the automated eGFR reporting
– Is reported with every request for SCr in individuals aged 18 years or more.
– Other newer markers such as Cystatin C and U-NGAL are available in other countries
– Currently not used in Australia
The University of Sydney Page 39
 – Protein and albumin
– Evaluation of urinary protein or albumin is now a standard tool to
characterize the severity of CKD and to monitor the rate of disease
progression
– Excessive amounts of proteins in the urine also indicates increased
cardiovascular risk
– Persistent proteinuria or albuminuria that is present on at least 3
occasions over a period of 3 to 6 months is now considered a principal
marker of kidney damage

The University of Sydney Page 40
 – Urine ACR predicts renal and CVD risk
– Urine ACR is more sensitive than Protein: Creatinine Ratio (PCR)
– Albuminuria is present if two out of three ACR tests are positive
– CKD is present if albuminuria is persistent at least for 3 months
– Hematuria
– In many people, haematuria is related to menstruation or UTI
– Persistent haematuria, or haematuria in conjunction with other indicators
of kidney damage needs further investigation
– Dipsticks may be used as a screening

The University of Sydney Page 41
The University of Sydney Page 42
The University of Sydney Page 43
 – Factors other than CKD known to increase albuminuria
– Urinary tract infection (UTI)
– High protein intake
– CCF
– Heavy exercise (within 24 hours)
– Drugs (NSAIDs)
– Hematuria
– In many people, haematuria is related to menstruation or UTI
– Persistent haematuria, or haematuria in conjunction with other indicators
of kidney damage needs further investigation
– Dipsticks may be used as a screening

The University of Sydney Page 44
 Drug Dosage Adjustment in Kidney Impairment
– Dose reduction of some drugs is recommended for people with
reduced kidney function
– eGFR provides a valid estimate of kidney drug clearance and
is widely available on laboratory reports.
– If using eGFR for drug dosing, body size should be considered,
in addition to referring to the approved product information.
– For drug dosing in very large or very small people, it may be
preferred to calculate an eGFR that is not normalised to
1.73m2 body surface area (BSA).

The University of Sydney Page 45
 Drug Dosage Adjustment in Kidney Impairment

– eGFR provides a valid estimate of kidney drug clearance and
is widely available on laboratory reports.
– For most drugs in clinical practice eGFR vs CG equations has no
major difference in dosage recommendations
– Caution is advised in special groups (amputees, obesity,
pregnancy) or when dealing with narrow therapeutic index
drugs
– Important to focus on the patient-related, disease-related and
medication-related characteristics and use clinical judgment

The University of Sydney Page 46
 Q&A

The University of Sydney Page 47
Kidney Disease:
Acute Kidney Injury

Presented by
Ronald Castelino
A/Prof in Clinical Pharmacy
Renal Pharmacist, Blacktown
Hospital, NSW
[email protected];
[email protected]

The University of Sydney Page 48
The University of Sydney Page 49
 LEARNING OBJECTIVES

– Understand the categorisation of the causes of AKI
– Identify risk factors for AKI
– Identify medications associated with AKI
– Formulate preventive strategies to decrease the risk of
developing AKI
– Formulate a therapeutic plan to manage AKI and its
complications

– Prerequisites
Before commencing this session you should have an understanding of: kidney
blood flow, glomerular filtration and plasma clearance
Tubular function and urine production

The University of Sydney Page 50
Acute Kidney Injury / Renal Failure

The University of Sydney Page 51
 – Abrupt decline in renal function leading to an increase in serum
concentrations of urea, creatinine & other substances (occurs
over a period of days)
– Common - occurs in 2% to 7% of all hospital admissions
– and in up to 36% to 67% of critically ill patients
– very common amongst the elderly
– may occur in someone either with previously normal renal
function or as an acute and unanticipated deterioration in
function in a patient with previously established chronic kidney
disease (“acute on chronic”)

The University of Sydney Page 52
The University of Sydney Page 53
The University of Sydney Page 54
The University of Sydney Page 55
 AUSTRALIAN CRITERIA FOR AKI

The University of Sydney Page 56
 STRATIFICATION OF AKI

The University of Sydney Page 57
 Diagnosis of AKI

The University of Sydney Page 58
 Estimating Kidney Function in AKI

– Difficult because commonly used SCr based equation are not
appropriate (assume stable SCr)
– Other equations such as Brater and Jeliffe may be more
accurate than Cockcroft-Gault but less tested

The University of Sydney Page 59
 Three categories of AKI
– Pre-renal (40-80% of cases)
– diseases characterized by renal hypo perfusion in which
the integrity of renal parenchymal tissue is preserved

– Intra-renal or intrinsic (10-50% of cases)
– diseases involving renal parenchymal tissue

– Post-renal or obstructive (160mg frusemide), but cease if no response
– for AIN, avoid offending agent in future
The University of Sydney Page 71
72

The University of Sydney Page 72
 – Post-renal
– relieve obstruction
– All patients with significant AKI also require attentive
management of volume, electrolyte (esp K+) and acid-
base status, and nutrition
– Renal replacement therapy (RRT, dialysis) may be
required in cases of severe AKI (hyperkalaemia,
volume overload, severe acidosis, or overt uraemia)

The University of Sydney Page 73
74

The University of Sydney Page 74
 – Severe hyperkalaemia (K+ >6.5 mmol/L) is a medical
emergency because of the risk of life threatening cardiac
arrhythmias

The University of Sydney Page 75
 Problem Management
Fluid volume disturbance Rehydrate (hypovolaemic); withhold fluid/high dose
diuretic (hypervolaemic); dialysis (resistant
pulmonary oedema)

Metabolic disturbances
Hyperkalemia IV calcium; bicarbonate; glucose+insulin; ion
exchange resin; dialysis

Acidosis Bicarbonate; dialysis
Uraemic symptoms Dialysis
Infection Antibiotics
Nutritional deficiencies Enteral nutrition; parenteral nutrition; dialysis

The University of Sydney Page 76
 – Optimising drug therapy for patients with AKI is challenging
– Factors that need considerations include; residual drug
clearance, accumulation of fluids, and dialysis.
– For renally cleared drugs (>30% elimination unchanged in the
urine), particularly for drugs with narrow therapeutic range,
serum drug concentration and pharmacodynamic response is
necessary.

The University of Sydney Page 77
 Q&A

The University of Sydney Page 78
 Case Examples
– An 84-year-old lady was admitted to a major teaching hospital with
complaints of chest pain. Cardiac issues were ruled out following
ECG and Troponins. She was diagnosed to have GORD and 2was also
noted to have an AKI on admission (eGFR: 14ml/min/1.73m 2.
).
Previous GP results 6 months ago was 54ml /min/1.73m
– Was discharged with Esomeprazole 40mg BD, Gaviscon 20ml TDS
prn with a discharge eGFR of 24ml
– Aprrox 5 months later presents to Blacktown hospital with similar
complaints. eGFR:12ml
– Medication history reports 6-8 tabs of QuickEze (each with 750mg
Calcium), taking Gaviscon and also Vitamin D 2 Caps for
osteoporosis
– Diagnosis: Calcium Alkali Syndrome, treated with Pamidronate and
hydration. Discharge eGFR of 52ml/min

– Clinical Tip: Always ask for OTC and other drugs
– https://onlinelibrary.wiley.com/doi/epdf/10.1002/jppr.1873

The University of Sydney Page 79